Alternative Splicing Determines the Function of CYP4F3 by Switching Substrate Specificity

Abstract

Diversity of cytochrome P450 function is determined by the expression of multiple genes, many of which have a high degree of identity. We report that the use of alternate exons, each coding for 48 amino acids, generates isoforms of human CYP4F3 that differ in substrate specificity, tissue distribution, and biological function. Both isoforms contain a total of 520 amino acids. CYP4F3A, which incorporates exon 4, inactivates LTB₄ by ω-hydroxylation (K_m = 0.68 μm) but has low activity for arachidonic acid (K_m = 185 μm); it is the only CYP4F isoform expressed in myeloid cells in peripheral blood and bone marrow. CYP4F3B incorporates exon 3 and is selectively expressed in liver and kidney; it is also the predominant CYP4F isoform in trachea and tissues of the gastrointestinal tract. CYP4F3B has a 30-fold higherK_m for LTB₄ compared with CYP4F3A, but it utilizes arachidonic acid as a substrate for ω-hydroxylation (K_m = 22 μm) and generates 20-HETE, an activator of protein kinase C and Ca²⁺/calmodulin-dependent kinase II. Homology modeling demonstrates that the alternative exon has a position in the molecule which could enable it to contribute to substrate interactions. The results establish that tissue-specific alternative splicing of pre-mRNA can be used as a mechanism for changing substrate specificity and increasing the functional diversity of cytochrome P450 genes.